Section 1: The Nature of Science Preview Key Ideas Bellringer How Science Takes Place The Branches of Science Scientific Laws and Theories
Key Ideas How do scientists explore the world? How are the many types of science organized? What are scientific theories, and how are they different from scientific laws?
How Science Takes Place How do scientists explore the world? A scientist may perform experiments to find a new aspect of the natural world, to explain a known phenomenon, to check the results of other experiments, or to test the predictions of current theories.
How Science Take Place, continued Scientists investigate. Scientists plan experiments. Scientists observe. Scientists always test the results.
The Branches of Science How are the many types of science organized? Most of the time, natural science is divided into biological science, physical science and Earth science. science: the knowledge obtained by observing natural events and conditions in order to discover facts and formulate laws or principles that can be verified or tested
The Branches of Science, continued The branches of science work together. biological science: the science of living things botany, ecology physical science: the science of matter and energy chemistry: the science of matter and its changes physics: the science of forces and energy earth science: the science of the Earth, the atmosphere, and weather
Visual Concept: Natural Science Click the button below to watch the Visual Concept.
Visual Concept: Biology Click the button below to watch the Visual Concept.
Visual Concept: Physics Click the button below to watch the Visual Concept.
Visual Concept: Earth Sciences Click the button below to watch the Visual Concept.
The Branches of Science, continued Science and technology work together. pure science: the continuing search for scientific knowledge Advances in science and technology depend on each other. technology: the application of science for practical purposes
Scientific Laws and Theories What are scientific theories, and how are they different from scientific laws? Theories explain why something happens, laws explain how something works. law: a descriptive statement or equation that reliably predicts events under certain conditions theory: a system of ideas that explains many related observations and is supported by a large body of evidence acquired through scientific investigation
Scientific Laws and Theories, continued Experimental results support laws and theories. Scientific theories are always being questioned and examined. To be valid, a theory must: explain observations be repeatable be predictable
Visual Concept: Comparing Theories and Laws Click the button below to watch the Visual Concept.
Scientific Laws and Theories, continued Mathematics can describe physical events. qualitative statement: describes something with words quantitative statement: describes something with mathematical equations
We use models in our everyday lives. Scientific Laws and Theories, continued Theories and laws are always being tested. Models can represent physical events. model: a representation of an object or event that can be studied to understand the real object or event Scientists use conceptual, physical, and computer models to study objects and events.
Visual Concept: Models Click the button below to watch the Visual Concept.
Visual Concept: Physical, Mathematical, and Conceptual Models Click the button below to watch the Visual Concept.
Section 2: The Way Science Works Preview Key Ideas Bellringer Science Skills Units of Measure Units of Measurement SI (Le Système Internationale d Unités) Math Skills
Key Ideas How can I think and act like a scientist? How do scientists measure things?
Science Skills How can I think and act like a scientist? Identifying problems, planning experiments, recording observations, and correctly reporting data are some of the most important science skills. Scientists approach a problem by thinking logically.
Science Skills, continued Critical thinking helps solve problems logically. critical thinking: the ability and willingness to assess claims critically and to make judgments on the basis of objective and supported reasons Scientists use scientific methods to solve problems. scientific method: a series of steps followed to solve problems including collecting data, formulating a hypothesis, testing the hypothesis, and stating conclusions The scientific methods are general description of scientific thinking rather than an exact path for scientists to follow.
Science Skills, continued Scientists test hypotheses. hypothesis: a possible explanation or answer that can be tested Scientists test a hypothesis by doing a controlled experiment. controlled experiment: an experiment in which the variables that could affect the experiment are kept constant (controlled) except for the one that you want to measure variable: a factor that changes in an experiment in order to test a hypothesis
Science Skills, continued Experiments test ideas. No experiment is a failure. The results of every experiment can be used to revise the hypothesis or plan tests of a different variable. Peer-reviewed research: research that has been reviewed by other scientists
Science Skills, continued Scientists use special tools. There are many tools used by scientists for making observations, including telescopes spectroscopes particle accelerators
Units of Measurement How do scientists measure things? Scientists use standard units of measure that together form the International System of Units, or SI.
Units of Measurement, continued SI units are used for consistency. SI has seven base units. derived units: combinations of the base units
Units of Measurement, continued SI prefixes are for very large and very small measurements. The prefixes are multiples of 10. SI prefixes for large measurements
Units of Measurement, continued SI prefixes for small measurements
Units of Measurement, continued You can convert between small and large numbers. To convert to a smaller unit, multiply the measurement by the ratio of units so that you get a larger number. To convert to a larger unit, divide the measurement by the ratio of units so that you get a smaller number.
Math Skills Conversions within SI The width of a soccer goal is 7 m. What is the width of the goal in centimeters? 1. List the given and unknown values. Given: length in meters, l = 7 m Unknown: length in centimeters =? cm
Math Skills, continued 2. Determine the relationship between units. 1 cm = 0.01 m 1 m = 100 cm Multiply by 100 because you are converting from meters, a larger unit, to centimeters, a smaller unit. 3. Write the equation for the conversion. length in cm = m 100 cm 1 m
Math Skills, continued 4. Insert the known values into the equation, and solve. length in cm = 7 m 100 cm 1 m length in cm = 700 cm
Units of Measurement, continued Measurements quantify your observations. length: a measure of the straight-line distance between two points mass: a measure of the amount of matter in an object volume: a measure of the size of a body or region in three-dimensional space weight: a measure of the gravitational force exerted on an object
Section 3: Organizing Data Preview Key Ideas Bellringer Presenting Scientific Data Writing Numbers in Scientific Notation Math Skills Using Significant Figures Accuracy and Precision, Part 1 Accuracy and Precision, Part 2
Key Ideas Why is organizing data an important science skill? How do scientists handle very large and very small numbers? How can you tell the precision of a measurement?
Bellringer Imagine your teacher asked you to study how the addition of different amounts of fertilizer affects plant heights. In your experiment, you collect the data shown in the table below. Use this data to answer the following questions.
Bellringer, continued 1. Which amount of fertilizer produced the tallest plants? 2. Which amount of fertilizer produced the smallest plants? 3. Plot the data on a grid like the one below.
Presenting Scientific Data Why is organizing data an important science skill? Because scientists use written reports and oral presentations to share their results, organizing and presenting data are important science skills.
Plotted on the y-axis Presenting Scientific Data, continued Line graphs are best for continuous change. dependent variable: values depend on what happens in the experiment Plotted on the x-axis independent variable: values are set before the experiment takes place
Line Graph
Presenting Scientific Data, continued Bar graphs compare items. A bar graph is useful for comparing similar data for several individual items or events. A bar graph can make clearer how large or small the differences in individual values are.
Bar Graph
Data in a pie chart is presented as a Presenting Scientific Data, continued Composition of a Winter Jacket Pie graphs show the parts of a whole. A pie graph is ideal for displaying data that are parts of a whole.
Writing Numbers in Scientific Notation How do scientists handle very large and very small numbers? To reduce the number of zeros in very big and very small numbers, you can express the values as simple numbers multiplied by a power of 10, a method called scientific notation. scientific notation: a method of expressing a quantity as a number
Writing Numbers in Scientific Notation, continued Some powers of 10 and their decimal equivalents are shown below. 10 3 = 1,000 10 2 = 100 10 1 = 10 10 0 = 1 10-1 = 0.1 10-2 = 0.01 10-3 = 0.001
Writing Numbers in Scientific Notation, continued Use scientific notation to make calculations. When you use scientific notation in calculations, you follow the math rules for powers of 10. When you multiply two values in scientific notation, you add the powers of 10.
Math Skills Writing Scientific Notation The adult human heart pumps about 18,000 L of blood each day. Write this value in scientific notation. 1. List the given and unknown values. Given: volume, V = 18,000 L Unknown: volume, V =? 10? L
Math Skills, continued 2. Write the form for scientific notation. V =? 10? L 3. Insert the known values into the form, and solve. Find the largest power of 10 that will divide into the known value and leave one digit before the decimal point. You get 1.8 if you divide 10,000 into 18,000 L.
Math Skills, continued Then, write 10,000 as a power of 10. 10,000 = 10 10 18,000 L can be written as 1.8 10 10 L V = 1.8 10 10 L
Math Skills Using Scientific Notation Your county plans to buy a rectangular tract of land measuring 5.36 x 10 3 m by 1.38 x 10 4 m to establish a nature preserve. What is the area of this tract in square meters? 1. List the given and unknown values. 4
Math Skills, continued 2. Write the equation for area. A = l w 3. Insert the known values into the equation, and solve. A = (1.38 10 4 m) (5.36 10 3 m) Regroup the values and units as follows. A = (1.38 5.36) (10 4 10 3 ) (m m) When multiplying, add the powers of 10. A = (1.38 5.35) (10 4+3 ) (m m) A = 7.3968 10 7 m 2 A = 7.40 10 7 m 2
Using Significant Figures How can you tell the precision of a measurement? Scientists use significant figures to show the precision of a measured quantity. precision: the exactness of a measurement significant figure: a prescribed decimal place that determines the amount of rounding off to be done based on the
Using Significant Figures, continued Precision differs from accuracy. accuracy: a description of how close a measurement is to the true value of the quantity measured
Accuracy and Precision, Part 1
Accuracy and Precision, Part 2
Visual Concept: Significant Figures
Using Significant Figures, continued Round your answers to the correct significant figures. When you use measurements in calculations, the answer is only as precise as the least precise measurement used in the calculation. The measurement with the fewest significant figures determines the number of significant figures that can be used in the answer.
Math Skills Significant Figures Calculate the volume of a room that is 3.125 m high, 4.25 m wide, and 5.75 m long. Write the answer with the correct number of significant figures. 1. List the given and unknown values. Given: length, l = 5.75 m width, w = 4.25 m height, h = 3.125 m
Math Skills, continued 2. Write the equation for volume. V = l w h 3. Insert the known values into the equation, and solve. V = 5.75 m 4.25 m 3.125 m V = 76.3671875 m 3 The answer should have three significant V = 76.4 m figures, because 3 the value with the smallest number of significant figures has three significant figures.